Multiple origins of obligate nematode and insect symbionts by a clade of bacteria closely related to plant pathogens

Multiple origins of obligate nematode and insect symbionts by a clade of bacteria closely related to plant pathogens

Obligate symbioses involving intracellular bacteria have transformed eukaryotic life, from providing aerobic respiration and photosynthesis to enabling colonization of previously inaccessible niches, such as feeding on xylem and phloem, and surviving in deep-sea hydrothermal vents. A major challenge...

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Published in:Proceedings of the National Academy of Sciences - PNAS Vol. 117; no. 50; pp. 31979 - 31986
Main Authors: Martinson, Vincent G., Gawryluk, Ryan M. R., Gowen, Brent E., Curtis, Caitlin I., Jaenike, John, Perlman, Steve J.
Format: Journal Article
Language:English
Published: United States National Academy of Sciences 15-12-2020
Subjects:
Aerobic respiration
Animals
Antibiotics
Bacteria
Biological Sciences
Colonization
Deep sea
Drosophila - microbiology
Drosophila - parasitology
Endosymbionts
Enterobacteriaceae - isolation & purification
Enterobacteriaceae - physiology
Genome, Bacterial - genetics
Genomes
Genomic analysis
Genomics
Howardula
Hydrothermal vents
Insects
Intracellular
Invertebrates
Nematodes
Niches
Parasites
Pectobacterium - genetics
Photosynthesis
Phylogeny
Pseudogenes
Pseudogenes - genetics
Rhabditida - microbiology
Rhabditida - physiology
Sibling species
Symbionts
Symbiosis
Symbiosis - physiology
Vents
Xylem
Sodalis
genome reduction
Howardula
Drosophila
symbiosis
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Summary:Obligate symbioses involving intracellular bacteria have transformed eukaryotic life, from providing aerobic respiration and photosynthesis to enabling colonization of previously inaccessible niches, such as feeding on xylem and phloem, and surviving in deep-sea hydrothermal vents. A major challenge in the study of obligate symbioses is to understand how they arise. Because the best studied obligate symbioses are ancient, it is especially challenging to identify early or intermediate stages. Here we report the discovery of a nascent obligate symbiosis in Howardula aoronymphium, a well-studied nematode parasite of Drosophila flies. We have found that H. aoronymphium and its sister species harbor a maternally inherited intracellular bacterial symbiont. We never find the symbiont in nematode-free flies, and virtually all nematodes in the field and the laboratory are infected. Treating nematodes with antibiotics causes a severe reduction in fly infection success. The association is recent, as more distantly related insect-parasitic tylenchid nematodes do not host these endosymbionts. We also report that the Howardula nematode symbiont is a member of a widespread monophyletic group of invertebrate host-associated microbes that has independently given rise to at least four obligate symbioses, one in nematodes and three in insects, and that is sister to Pectobacterium, a lineage of plant pathogenic bacteria. Comparative genomic analysis of this group, which we name Candidatus Symbiopectobacterium, shows signatures of genome erosion characteristic of early stages of symbiosis, with the Howardula symbiont’s genome containing over a thousand predicted pseudogenes, comprising a third of its genome.
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Author contributions: V.G.M., R.M.R.G., C.I.C., J.J., and S.J.P. designed and performed experiments, analyses, and sequencing; B.E.G. performed electron microscopy; and V.G.M. and S.J.P. wrote the paper with input from all the authors.
Edited by Joan E. Strassmann, Washington University in St. Louis, St. Louis, MO, and approved October 10, 2020 (received for review January 15, 2020)
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.2000860117